CN109479293A - The method and device thereof of signal are sent or received in a wireless communication system - Google Patents
The method and device thereof of signal are sent or received in a wireless communication system Download PDFInfo
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- CN109479293A CN109479293A CN201880002805.6A CN201880002805A CN109479293A CN 109479293 A CN109479293 A CN 109479293A CN 201880002805 A CN201880002805 A CN 201880002805A CN 109479293 A CN109479293 A CN 109479293A
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04W—WIRELESS COMMUNICATION NETWORKS
- H04W72/00—Local resource management
- H04W72/20—Control channels or signalling for resource management
- H04W72/23—Control channels or signalling for resource management in the downlink direction of a wireless link, i.e. towards a terminal
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04L—TRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
- H04L5/00—Arrangements affording multiple use of the transmission path
- H04L5/0001—Arrangements for dividing the transmission path
- H04L5/0014—Three-dimensional division
- H04L5/0023—Time-frequency-space
-
- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04L—TRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
- H04L5/00—Arrangements affording multiple use of the transmission path
- H04L5/003—Arrangements for allocating sub-channels of the transmission path
- H04L5/0048—Allocation of pilot signals, i.e. of signals known to the receiver
- H04L5/0051—Allocation of pilot signals, i.e. of signals known to the receiver of dedicated pilots, i.e. pilots destined for a single user or terminal
-
- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04L—TRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
- H04L5/00—Arrangements affording multiple use of the transmission path
- H04L5/003—Arrangements for allocating sub-channels of the transmission path
- H04L5/0053—Allocation of signaling, i.e. of overhead other than pilot signals
-
- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04L—TRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
- H04L5/00—Arrangements affording multiple use of the transmission path
- H04L5/0091—Signaling for the administration of the divided path
- H04L5/0094—Indication of how sub-channels of the path are allocated
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04W—WIRELESS COMMUNICATION NETWORKS
- H04W72/00—Local resource management
- H04W72/04—Wireless resource allocation
- H04W72/044—Wireless resource allocation based on the type of the allocated resource
- H04W72/0453—Resources in frequency domain, e.g. a carrier in FDMA
-
- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04W—WIRELESS COMMUNICATION NETWORKS
- H04W72/00—Local resource management
- H04W72/04—Wireless resource allocation
- H04W72/044—Wireless resource allocation based on the type of the allocated resource
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- Engineering & Computer Science (AREA)
- Signal Processing (AREA)
- Computer Networks & Wireless Communication (AREA)
- Mobile Radio Communication Systems (AREA)
Abstract
According to one embodiment of present invention, a kind of includes: in a wireless communication system the information of frequency resource of the first CORESET configuration including the first CORESET the step of receiving the first control resource set (CORESET) configuration by the method that terminal receives down link signal;And the step of physical downlink control channel (PDCCH) signal is received by bundling multiple resource element groups (REG) on the first CORESET, wherein the information of the frequency resource of the first CORESET is bitmap, and bitmap can be using 6-RB as the first CORESET of unit dividing frequency resource, so that every 2,3 or 6 REG are not belonging to the surplus resources that any REG is bundled after being bundled into 1 REG binding in the first CORESET.
Description
Technical field
The present invention relates to wireless communication system, more particularly, to sending and receiving downlink chain in a wireless communication system
The method and apparatus of road (DL) control channel signal.
Background technique
Firstly, will be briefly described existing 3GPP LTE/LTE-A system.Search of initial zone is executed with reference to Fig. 1, UE
(S101).In initial cell search procedure, UE receives primary synchronization channel (P-SCH) and auxiliary synchronization channel (S-SCH) from base station,
Downlink synchronization is executed with BS, and obtains the information of such as cell ID.Hereafter, UE is obtained by PBCH (Physical Broadcast Channel)
System information (for example, MIB).UE can receive DL RS (downlink reference signal) and check downlink channel status.
After search of initial zone, UE can be by receiving the physical downlink control channel dispatched by PDCCH
(PDCCH) and physical downlink control channel (PDSCH) obtains more detailed system information (for example, SIB) (S102).
UE can execute the random access procedure for uplink synchronisation.UE passes through Physical Random Access Channel
(PRACH) send leading (for example, Msg1) (S103), and by PDCCH and PDSCH corresponding with PDCCH reception be used for before
The response message (for example, Msg2) led.In the case where random access competition-based, such as additional PRACH can be executed and passed
Defeated (S105) and PDCCH/PDSCH receive the contention resolved process of (S106).
Then, UE can execute PDCCH/PDSCH and receive (S107) and physical uplink shared channel (PUSCH)/object
It manages uplink control channel (PUCCH) transmission (S108) and is used as general uplink/downlink signals transmission.UE
BS can be sent by UCI (uplink control information).UCI may include HARQ ACK/NACK (hybrid automatic repeat-request
Confirmation/negative ACK), SR (scheduling request), CQI (channel quality indicator), PMI (precoding matrix indicators) and/or RI
Deng.
Summary of the invention
Technical problem
It is used to pass through under physics in a wireless communication system it is an object of the invention to one kind designed for what is solved the problems, such as
Uplink Control Channel (PDCCH) signal is more effectively and the method and apparatus that accurately send or receive signal.
It should be understood that aforementioned general description of the invention and it is described in detail below be all exemplary and illustrative, and purport
Further explanation to claimed invention is being provided.
Technical solution
It, can be with by providing the method for receiving downlink (DL) signal by user equipment (UE) in a wireless communication system
It achieves the object of the present invention, this method comprises: the first control resource set (CORESET) configuration is received, the first CORESET configuration packet
The information of the frequency resource about the first CORESET is included, and by bundling multiple resource element groups on the first CORESET
(REG) physical downlink control channel (PDCCH) signal is received, wherein the letter of the frequency resource about the first CORESET
Breath is bitmap;And its Bitmap distributes the frequency resource of the first CORESET as unit of 6-RB, so that at every 2,3 or 6
REG is not belonging to the surplus resources that any REG is bundled after being bundled into 1 REG binding in the first CORESET.
In another aspect of this invention, it provides here a kind of in a wireless communication system by base station (BS) transmission downlink chain
The method of road (DL) signal, this method comprises: the first control resource set (CORESET) configuration is sent, the first CORESET configuration packet
The information of the frequency resource about the first CORESET is included, and by bundling multiple resource element groups on the first CORESET
(REG) physical downlink control channel (PDCCH) signal is sent, wherein the letter of the frequency resource about the first CORESET
Breath is bitmap;And its Bitmap distributes the frequency resource of the first CORESET as unit of 6-RB, so that at every 2,3 or 6
REG is not belonging to the surplus resources that any REG is bundled after being bundled into 1 REG binding in the first CORESET.
In another aspect of this invention, it provides here a kind of for receiving the user equipment of downlink (DL) signal
Including receiver (UE),;Processor is used to configure using the first control resource set (CORESET) of receiver reception, first
CORESET configuration includes the information about the frequency resource of the first CORESET, and more by bundling on the first CORESET
A resource element groups (REG) receive physical downlink control channel (PDCCH) signal, wherein about the first CORESET's
The information of frequency resource is bitmap;And its Bitmap distributes the frequency resource of the first CORESET as unit of 6-RB, so that
Every 2,3 or 6 REG are not belonging to the surplus of any REG binding after being bundled into 1 REG binding in the first CORESET
Remaining resource.
In another aspect of this invention, a kind of base station (BS) for being used to send downlink (DL) signal is provided here,
Including transmitter;Processor sends the first control resource set (CORESET) using transmitter and configures, the first CORESET configuration
Information including the frequency resource about the first CORESET, and by bundling multiple resource element groups on the first CORESET
(REG) physical downlink control channel (PDCCH) signal is sent, wherein the letter of the frequency resource about the first CORESET
Breath is bitmap;And its Bitmap distributes the frequency resource of the first CORESET as unit of 6-RB, so that at every 2,3 or 6
REG is not belonging to the surplus resources that any REG is bundled after being bundled into 1REG binding in the first CORESET.
Bitmap specific configuration can be used for the subband that UE is operated in multiple subbands.The multiple bits for including in bitmap
Each of can correspond to 6-RB, and each bit value indicate corresponding 6-RB whether be the first CORESET frequency
Resource.
UE can use identical precoding at least for the REG for belonging to identical REG binding.
First CORESET configuration can also include that REG bundlees size information.
REG binding size applied to the first CORESET can be considered at least partly Chong Die with the first CORESET the
The REG of two CORESET bundlees size to determine.
Match when for the first CORESET and with one in the first CORESET at least partly be overlapped the 2nd CORESET
When setting intertexture, intertexture can be executed based on including the REG binding collection of multiple REG binding.
It can determine that the quantity for the multiple REG binding for including, and multiple REG are concentrated in REG binding according to polymerization grade
Binding can be belonging respectively to different control channel elements (CCE).
In the first CORESET and the 2nd CORESET, about the CORESET for not configuring intertexture to it, only the first polymerization
Grade collection { 1,2,4,8 } is available, and about the CORESET for being configured with intertexture to it, other than the first polymerization grade collection, the
Dimerization grade collection { 1,3,6,12 } also can be used.
May be considered as the first CORESET configuration binding size and whether to the first CORESET application intertexture and with
At least one of configuration of the 2nd CORESET of first CORESET overlapping will be applied to the polymerization of the first CORESET to determine
Grade collection.
1 REG can correspond to 1 in time domain symbol and correspond to 1 resource block (RB) on frequency domain.
Beneficial effect
According to an embodiment of the invention, since 2,3 or 6 REG are bundled into 1 REG binding to be used in CORESET
PDCCH signal sends and receives, therefore more accurately and can be more effectively carried out the channel estimation of PDCCH signal, because
The frequency resource of CORESET is to be distributed as unit of 6-RB by bitmap, it is possible to not generate the remaining money according to REG binding
Therefore source can more efficiently use the radio resource of CORESET.
It will be understood by those skilled in the art that the effect that can realize through the invention is not limited to be particularly described above
Effect, and other advantages of the invention will be more clearly understood from described in detail below in conjunction with attached drawing.
Detailed description of the invention
Fig. 1 is shown physical channel used in 3GPP LTE/LTE-A system and is transmitted using the general signal of physical channel
Method.
Fig. 2 is the figure for explaining the problem when the REG binding grid between different CORESET mismatches.
Fig. 3 is the exemplary figure for showing the obstruction between the AL candidate for belonging to different CORESET.
Fig. 4 is another exemplary figure for showing the obstruction between intertexture CORESET and non-interwoven CORESET.
Fig. 5 shows the REG binding collection of the CCE and intertexture CORESET of non-interwoven CORESET.
Fig. 6 is to show the case where 1 symbol CORESET and 2 symbol CORESET of embodiment according to the present invention overlaps each other
Figure.
Fig. 7 shows the process of the method for sending and receiving downlink (DL) signal of embodiment according to the present invention.
Fig. 8 shows base station (BS) and the user equipment (UE) of embodiment according to the present invention.
Specific embodiment
Various wireless access systems can be applied to the description of the embodiment of the present invention below, including (code point is more by CDMA
Location), FDMA (frequency division multiple access), TDMA (time division multiple acess), OFDMA (orthogonal frequency division multiple access), SC-FDMA (single-carrier frequency division multiple access)
Deng.CDMA can be realized with radio technologies such as UTRA (universal terrestrial radio accesses), CDMA 2000.TDMA can
With fast with such as GSM/GPRS/EDGE (global system for mobile communications)/General Packet Radio Service/GSM evolution enhancing data
The radio technology of rate is realized.OFDMA can with such as IEEE 802.11 (Wi-Fi), IEEE 802.16 (WiMAX),
The radio technologies such as IEEE 802.20, E-UTRA (evolution UTRA) are realized.UTRA is UMTS (Universal Mobile Telecommunications System)
A part.3GPP (third generation partner program) LTE (long term evolution) is the E-UMTS (evolution UMTS) using E-UTRA
A part.3GPP LTE uses OFDMA in the downlink, uses SC-FDMA in the uplink.LTE-A (LTE- is advanced)
It is the evolution version of 3GPP LTE.
For the sake of clarity, it is described below and relates generally to 3GPP LTE system or 3GPP lte-a system, it can be with by it
Technical concept of the invention is not limited.Offer be described below used in specific term be to help understanding the present invention, and
The use of term can be modified to different forms in the range of technical concept of the invention.
More and more communication equipments need higher and higher communication capacity, therefore, with the next generation communication system discussed recently
Conventional wireless in system is electrically accessed technology (RAT) and compares, mobile broadband (eMBB) communication for needing to enhance.In addition, for connecting
Multiple equipment and object to provide the large-scale machines type communication (mMTC) and next generation communication of various services whenever and wherever possible
In one of the factor to be considered.Furthermore, it is contemplated that being directed to service/user equipment (UE) of reliability and latency sensitive
Next generation communication system discusses super reliable low delay communication (URLLC).
Therefore, the new RAT for considering eMBB, mMTC, URLCC etc. has been discussed for next generation wireless communication.
Not with the design of new RAT, inconsistent some LTE/LTE-A operation and configuration also can be applied to new RAT.For side
Just for the sake of, new RAT can be described as 5G mobile communication.
<NR frame structure and physical resource>
In NR system, downlink (DL) and uplink can be executed by the frame with the 10ms duration
(UL) it transmits, and each frame may include 10 subframes.Therefore, 1 subframe can correspond to 1ms.Each frame is segmented into
Two fields.
1 subframe may include Nsymb subframe,μ=Nsymb slot×Nslot subframe,μA continuous OFDM symbol.Nsymb slot
Indicate the symbolic number of each time slot, μ indicates OFDM parameter set, and Nslot Subframe, μIndicate every subframe d time slot about corresponding μ
Number.In NR, multiple OFDM parameter sets shown in the following table 1 can be supported.
[table 1]
μ | Δ f=2μ·15[kHz] | Cyclic prefix |
0 | 15 | Normally |
1 | 30 | Normally |
2 | 60 | Normally, it extends |
3 | 120 | Normally |
4 | 240 | Normally |
In table 1 above, Δ f refers to subcarrier spacing (SCS).It can be that UE is configured about DL load via UL signaling
The μ and cyclic prefix of wavestrip wide portion (BWP) and μ and cyclic prefix about UL carrier wave BWP.
Table 2 below shows the quantity N of the symbol of time slot every in the case where normal CPsymb slot, the symbol of every frame
Quantity Nslot frame, and the number of timeslots N of every frame about each SCSslot Subframe, μ。
[table 2]
Table 3 below shows the quantity N of the symbol of time slot every in the case where extending CPsymb slot, the time slot of every frame
Quantity Nslot Frame, μ, and the number of timeslots N of every frame about each SCSslot Subframe, μ。
[table 3]
In this way, can be changed according to subcarrier spacing (SCS) in NR system including the time slot in 1 subframe
Quantity.The OFDM symbol for including in each time slot can correspond to any one of D (DL), U (UL) and X (flexible).It can be with
DL transmission is executed in D or X symbol, and UL transmission can be executed in U or X symbol.Flexible resource (for example, X symbol)
It is properly termed as retaining resource, other resources or unknown resources.
In NR, a resource block (RB) can correspond to 12 subcarriers in frequency domain.RB may include multiple OFDM
Symbol.Resource element (RE) can correspond to 1 subcarrier and 1 OFDM symbol.Therefore, 1 OFDM symbol in 1 RB
It is upper to may exist 12 RE.
Carrier wave BWP can be defined as one group of continuous Physical Resource Block (PRB).Carrier wave BWP can also be simply referred as
BWP.It can be most 4 BWP of each UL/DL link configuration in 1 UE.It, can also be given even if being configured with multiple BWP
1 BWP is activated in period.However, may further be SUL as configuration supplement uplink (SUL) in UE and configure 4
BWP, and 1 BWP can be activated in given time period.UE may not be expected from the DL BWP of activation receive PDSCH,
PDCCH, channel state information-reference signal (CSI-RS) or track reference signal (TRS).In addition, UE may not be expected from sharp
PUSCH or PUCCH is received in UL BWP living.
<NR DL control channel>
In NR system, the transmission unit of control channel can be defined as resource element groups (REG) and/or control channel
Element (CCE) etc..CCE can be the minimum unit for referring to control transmission.That is, minimum PDCCH size can correspond to
In 1 CCE.When polymerization grade is equal to or more than 2, multiple CCE can be grouped to send a PDCCH (that is, CCE by network
Polymerization).
REG can correspond to 1 OFDM symbol in time domain, and can correspond to 1 PRB in frequency domain.In addition, 1
A CCE can correspond to 6 REG.
It will now briefly be described control resource set (CORESET) and search space (SS).CORESET can be for controlling letter
One group of resource of number transmission, and search space can be the polymerization of the control channel candidate for executing blind Detecting.Can be
CORESET configures search space.For example, can be respectively provided for when defining a search space on a CORESET
The CORESET of public search space (CSS) and the CORESET for being used for the specific search space UE (USS).As another example, may be used
To define multiple search spaces in a CORESET.For example, CSS and USS may be configured to identical CORESET.With
In lower example, CSS can refer to the CORESET with the CSS for its configuration, and USS can refer to have for its configuration
The CORESET etc. of USS.
ENB can signal the information about CORESET to UE.For example, can be signaled to UE each
The CORESET of CORESET is configured, and can be in duration (for example, 1/2/3 symbol), corresponding of corresponding CORESET
The frequency domain resource of CORESET, precoder granularity, REG to CCE map type (for example, intertexture/non-interwoven), REG bundle size
CORESET configuration is signaled with the interleaver size etc. in REG to the CCE map type of intertexture.
When REG to the CCE mapping about 1 symbol CORESET is non-weave type, 6 REG about CCE are grouped
It is bundled to a REG, and all REG of corresponding CCE can be continuously.When there are (examples when multiple CCE in 1 PDCCH
Such as, when polymerization grade is equal to or more than 2), CCE is also possible to continuously.UE can be in 1 REG binding using identical
Precoding, or multiple REG can be bundled and use identical precoding.
When REG to the CCE mapping about 1 symbol CORESET is weave type, 2,3 or 6 REG can configure 1
REG binding.For example, and not all REG binding size 2,3 and 6 be all supported, but as its subset, for example, REG bundlees size
{ 2 }, { 3 }, { 2,3 }, { 2,6 }, { 3,6 } or { 2,3,6 } can be supported.When supporting binding size { 2,6 } REG, 2 REG
1 REG binding or 6 REG, which can be configured, can configure 1 REG binding.UE can be in 1 REG binding using identical
Precoding, or can according to precoder granularity for multiple REG use identical precoding.
It, can be in the case where being mapped about REG to the CCE with 2 symbols or the CORESET of bigger duration
REG binding is defined in time domain/frequency domain.When defining REG binding in the time domain, all REG for belonging to 1 REG binding can be with
Belong to identical RB and can correspond to different symbols.When defining REG binding in time-frequency domain, 1 REG binding can be with
Including belong to the REG of different RB and belong to identical RB and correspond to distinct symbols REG.
For REG to the CCE mapping with 2 symbols or the CORESET of bigger duration, it can support that the time is excellent
First map.It can support to configure REG binding in a manner of identical with the temporal duration of CORESET in the time domain.In non-friendship
In the case where knitting type, 6 REG for including in CCE can correspond to 1 REG binding, and the REG of corresponding CCE can be located at
In time domain/frequency domain.In the case where weave type, 2,3 or 6 REG can correspond to 1 REG binding, and REG binding can
To be bundled in CORESET.UE can use identical precoding in 1 REG binding, or can be according to precoder
Granularity uses identical precoding for multiple REG.
It discusses about the time domain precoder circulation with 2 symbols or the CORESET of bigger duration, and
For this purpose, can it is identical by with 1 symbol CORESET the case where in a manner of execute and correspond to 1 symbol in the time domain or REG is arrived
The REG binding of CCE mapping.It can support the mapping of 1 PDCCH candidate on multiple symbols.
From the above discussion, size being bundled according to REG, binding region is determined in time domain/frequency domain.However, being distributed
It may not yet determine in formula mapping (that is, interleaving conditions) and be bundled between REG is bundled.
REG binding may be needed to introduce to enhance the channel estimating performance of control channel.On the other hand, when introducing REG bundle
When tying up, need to overcome the problems, such as in terms of configuring mismatch with CORESET, it is candidate in the control channel for belonging to different CORESET
Between blocking probability increase aspect the problem of.
The embodiment of the present invention proposes solution to the problem.Implementation can individually be implemented or be combined to following instance.
Hereinafter, Distributed C ORESET or intertexture CORESET, which may mean that distribution and be arranged in corresponding CORESET, configures one
REG (REG binding or REG binding collection) of a CCE etc..
It is mismatched between problem 1:CORESET bandwidth and REG binding
REG binding can be configured as 1,2,3 or 6 REG (or RB) in a frequency domain, and if CORESET bandwidth
(BW) (that is, size of the CORESET in frequency domain) is not the multiple for bundling size, then may be not belonging to the surplus of REG binding
Remaining resource.Accordingly, it may be desirable to the method for handling the surplus resources of CORESET.
For example, in this regard, when frequency domain binding size is 3, a REG can when CORESET bandwidth is 100 RB
To be retained as cannot be used for the surplus resources of control channel transmission.When the position of non-accurate definition surplus resources, in network
May be different to the understanding of REG binding between UE, accordingly, it is possible to be unable to ensure channel estimating performance, and work as different UE
When assuming different surplus resources positions in identical CORESET, the blocking probability between control channel candidate can be can increase.Cause
This, is described below the method for overcoming these problems.
(1) it is distributed about the frequency domain resource of CORESET
Surplus resources are generated about all binding sizes (for example, 2,3 or 6 REG) in order to prevent, are proposed with 6 RB
For the frequency domain resource distribution for the CORESET that unit executes.1 REG can correspond to 1 RB in frequency domain, and in this regard,
When CORESET distributes (its least common multiple (for example, 6*N RB) for being all binding sizes) as unit of 6 RB, even if
Using any binding size of 2,3 and 6 REG, surplus resources are not also generated.It is big when determining that frequency domain bundlees for each CORESET
Hour, CORESET resource allocation is executed as unit of size can also being bundled by frequency domain.
For example, can define resource allocation unit=6 CORESET RB (or can be defined as corresponding CORESET
Frequency domain bundle size), and can with the resource allocation unit in corresponding CORESET configure REG bundle grid.Network/UE
Intertexture etc. can be executed based on REG binding grid.
In order to distribute the resource of CORESET in a frequency domain, it may be considered that following option.
Option 1: CORESET resource in frequency domain can with the beginning PRB index (for example, PRB is deviated) of CORESET and
Combination for configuring the quantity of the resource allocation unit of CORESET defines.For example, network can by PRB index 0 (for example,
The beginning PRB of CORESET) and 20 resource allocation units (for example, 20*6 PRB) be configured to CORESET BW.As PRB rope
The minimum PRB of the example drawn, system BW can be configured as PRB index 0.When system BW be divided into multiple sub- BW (for example,
BWP when) and UE is based on sub- BW operation, the minimum PRB of every sub- BW can be configured as PRB index 0.For example, PRB index can
It is specifically executed with sub- BW.When defining multiple carrier waves, PRB index 0 can be the minimum PRB of each carrier wave or in carrier wave
In include multiple sub- BW in operate UE sub- BW minimum PRB, but not limited to this.
Option 2: the bitmap based on resource allocation unit (or binding size)
Network can pass through the position based on resource allocation unit about system BW or subband described in option 1
Figure to configure CORESET BW to UE.For example, it is assumed that resource allocation unit is 6 RB, each position of bitmap can correspond to 6
RB。
Option 2 does not conflict with option 1, accordingly it is also possible to be interpreted to signal resource allocation unit in option 1
The method detailed of quantity.In addition, when group BW specifically executes PRB, can sub- BW specifically configure bitmap.
(2) surplus resources configure
When using not preventing from generating the CORESET resource allocation methods of surplus resources, determining surplus resources are proposed
Position method.
The position of surplus resources can be it is predefined, or can be by network configuration (for each CORESET).Example
Such as, when in specific CORESET generate surplus resources when, surplus resources can be predefined as positioned at CORESET starting point and/
Or terminal, or can be by network configuration.
Problem 2: the obstructing problem between multiple CORESET
When configuring multiple CORESET for a UE with for NR PDCCH when sending and receiving, different CORESET
It can partially overlap each other.The case where overlapping each other for CORESET, if REG binding grid is right not between CORESET
Together, then the REG binding of specific CORESET can be Chong Die with multiple REG of another CORESET binding.That is, blocking probability
It can increase and may seriously reduce resource utilization.
Fig. 2 is the figure for explaining the problem when the REG binding grid between different CORESET mismatches.
CORESET 0 and CORESET 1 are overlapped, in this case, it is assumed that the duration of CORESET 0 and CORESET 1
Duration it is identical, the frequency domain binding size of the frequency domain of CORESET 0 binding size and CORESET 1 are identical, and REG
Binding boundary is misaligned between COREST.
With reference to Fig. 2, the CCE of CORESET 1 can be Chong Die with 2 CCE of CORESET 0.Therefore, when CORESET1's
When CCE is used for particular UE, network cannot use 2 CCE of CORESET0, thus waste of resource.In order to solve this problem, it is proposed that
Following methods.
(3) belong to the boundary alignment between the REG binding of different CORESET
In Fig. 2, there are the following problems: REG binding boundary is aligned to improve not between CORESET obstruction generally
Rate, and in order to solve this problem, the following options are available.
Option 1: the starting location offset of REG binding is configured for each CORESET
For example, network can configure the initial position of REG binding for each CORESET.UE can be from for each
The initial position of the REG binding of CORESET configuration determines binding side as unit of corresponding to the binding size configured in CORESET
Boundary.
Option 2: the global reference on boundary is bundled
In order to determine binding boundary, predefined global reference or can be referred to by the network configuration overall situation.
For example, the initial position of system BW and synchronization signal (or PBCH), public money associated with initial access process
The starting point etc. in source may be used as global reference.Know that the UE of (or being configured with) global reference can be using from overall situation reference
Size is bundled to determine the binding boundary of corresponding CORESET.
UE can be each CORESET configuration binding boundary according to option 1 or 2 above.As binding boundary and CORESET
Boundary when being unmatched each other, it can be assumed that not exclusively include the REG binding in CORESET (for example, one of REG binding
Divide except the boundary of CORESET) it is not used in control transmission.
(4) the binding size alignment being overlapped between CORESET
The binding boundary between the CORESET with identical binding is described by reference to Fig. 2 above to mismatch to mention
The case where high blocking probability, therefore, even if binding boundary matches each other, when the binding of CORESET is of different sizes, it is also possible to go out
The now problem similar with Fig. 2.
For example, when bundle size be configured differently for be overlapped CORESET and bundle starting point it is identical when,
Binding boundary between CORESET can be matched each other with the interval of the least common multiple of each binding size, therefore, corresponding sides
Blocking probability in boundary may improve.
In order to solve this problem, the configuration of the frequency domain binding of the CORESET when different CORESET overlap each other is proposed
Size having the same.For example, identical frequency domain binding size may include in the CORESET configuration signaled by network
In.Alternatively, can use in conjunction with another information element (for example, CORESET duration) that CORESET is configured rather than individually
Signal notifies to determine that frequency domain bundlees size, it means that one of the binding size of corresponding CORESET is confirmed as representative bundle
Tie up size.
It can be assumed for instance that CORESET 0 is configured as 1 symbol duration, CORESET 1 is configured as 2 symbols
Number duration.When the frequency domain of CORESET 0/1 is tied to 6/3, representativeness binding size can be determined as 3.Work as CORESET
Duration is 2 and application time when preferentially mapping (since 1 CCE includes 6 REG, do not apply and bundle between CCE),
Frequency domain binding size may only have 1 or 3, and therefore, it can be interpreted that bundling size 3 is commonly used in two CORESET.
Problem 3: the obstructing problem between the different polymerization grades candidate of different CORESET
When the CORESET using intertexture and the CORESET without using intertexture are not overlapped, it is understood that there may be belong to using intertexture
CORESET high polymerization grade (AL) control channel candidate resource blockage without using interweave CORESET multiple controls
The probability of channel candidate.
Fig. 3 is the exemplary figure for showing the obstruction between the AL candidate for belonging to different CORESET.
Assume that in CORESET 0 without using interweave, and in CORESET 1 using interweave, and in fact it is thick
Line indicates some resources that AL4 control channel candidate is configured in CORESET 1.It assume that in CORESET 1 in frequency domain
It is candidate that upper 12 REG binding with binding size 2 configures an AL4 control channel, and 12 REG bindings can be equably
It is distributed on frequency domain.
Although Fig. 3 shows some resources for blocking CORESET 1 in the worst cases, the AL4 control of CORESET 1
12 CCE of channel candidate obstruction CORESET 0 processed.
On the other hand, in fact it could happen that the problem of be CORESET 0 high AL control channel candidate block CORESET 1 it is more
A control channel is candidate.
When being overlapped each other using the CORESET of different mappings method (for example, intertexture/non-interwoven), control channel is candidate
The method for occupying resource is different each CORESET, therefore, obstructing problem inevitably occurs.Hereinafter, it mentions
A kind of method for minimizing obstructing problem is gone out.
(5) intertexture based on REG binding collection
As shown in figure 3, when intertexture CORESET and non-interwoven CORESET overlap each other, if intertexture CORESET's
In the case of the REG of one control channel candidate of configuration bundle and be uniformly distributed (in CORESET), then be likely to occur obstructing problem,
Because of the candidate obstruction mutually of the control channel of difference CORESET.
As the method for minimizing such case, the intertexture as unit of REG binding collection is proposed.REG binding collection can be with
Refer to the polymerization for configuring the REG binding of different CCE.
It can be assumed for instance that executing intertexture and REG binding size to AL2 control channel candidate is 2 REG.Network/UE
It can be in CCE 0 (=REG bundlees 0+REG binding 1+REG binding 2) and CCE1 (=REG bundlees 3+REG binding 4+REG binding 5)
Each in selection 1 REG binding, configure AL2 control channel candidate to configure 1 REG binding collection.As a result, can give birth to
At 3 REG binding collection.For example, bundling 1+REG as REG binding collection 0=REG binding 0+REG bundlees 3, REG binding collection 1=REG
Binding 4, REG binding collection 2=REG binding 2+REG, which bundlees 5,3 REG binding collection, to be determined.Network/UE can be tied with REG
It ties up to integrate and executes intertexture as unit.
In this way, when executing the intertexture based on REG binding collection, AL2 control channel candidate in the CORESET of intertexture can be with
3 AL1 control channels for only blocking the CORESET of non-interwoven are candidate.When the AL2 control channel for the CORESET that configuration interweaves is waited
Choosing REG binding be evenly distributed in CORESET (that is, by REG bundle as unit of be interleaved) when, intertexture CORESET's
6 AL1 control channels that AL2 control channel candidate can block the CORESET of non-interwoven are candidate.
When executing the intertexture based on REG binding collection, the size of REG binding collection can be configured differently according to target AL.
When the CORESET that network configuration interweaves is suitably to reflect channel situation etc., network can be only fitted in corresponding CORESET and answer
The size (or target AL) of REG binding collection.It means that frequency diversity gain subtracts when the size of REG binding collection increases
It is small, and when the size of REG binding collection reduces, frequency diversity gain increases.When supporting the binding between REG binding, REG
The size of binding collection increases, it means that enhances channel estimating performance.For example, being bundled when being executed using target AL4 based on REG
When the intertexture of collection, 4 REG bindings (extracting from 4 CCE of configuration AL4 control channel candidate respectively) can configure a REG
Binding collection.
(6) configurability of polymerization grade
It, can compared with the case where executing the intertexture based on REG binding unit when executing the intertexture based on REG binding collection
To reduce blocking probability, but in this case, obstruction can be can increase by bundling size according to the frequency domain of the CORESET of non-interwoven
Probability.
Fig. 4 is another exemplary figure for showing the obstruction between the CORESET of intertexture and the CORESET of non-interwoven.In Fig. 4
In, it can be assumed that the duration of the CORESET of intertexture is 3 symbols, and the duration of the CORESET of non-interwoven is 1
A symbol.
1 CCE=6 REG is defined, therefore, maintains traditional 1,2,4 and of AL when intertexture of the execution based on REG binding collection
When 8, the frequency domain initial position of each REG binding collection and the frequency domain initial position of the CCE in non-interwoven CORESET need to be aligned with
It is effectively reduced blocking probability.However, in this case, it is possible to generate cannot be in resource used in the CORESET of intertexture.
For example, may include for the REG binding of AL4 control channel candidate setting in the CORESET of intertexture in Fig. 4
In a CCE of the CORESET of non-interwoven in a frequency domain, but the endpoint of REG binding collection may be with the end of CCE not
Match, thus waste of resource.
In order to reduce the wasting of resources, proposes and introduce AL { 1,3,6,12 } and AL { 1,2,4,8 }.However, the present invention is not
It is limited to AL { 1,3,6,12 }, and can be not excluded for using other AL.
When using { 1,3,6,12 } AL, the REG binding collection in the CORESET of intertexture for AL 3,6,12 can hinder
1/2,1 and 2 CCE of the CORESET of non-interwoven is filled in, therefore, the wasting of resources can be reduced to utmostly.AL{1,3,6,12}
It can be only applied to the CORESET to interweave.Network can for interweave CORESET configuration AL collection { 1,2,4,8 } and 1,3,6,
12 } one in.For example, AL { 1,2,4,8 } can also be only limitted to the case where frequency domain binding size of CORESET is 3.
Alternatively, network can also be configured to support the AL of each CORESET for each CORESET.Example
Such as, the available AL of network can be { 1,2,3,4,6,8,12 }, and network can be configured in specific CORESET it is some corresponding
AL.It alternatively, various combined AL collection can be defined as to table, and can be each AL collection index in respective table
CORESET Configuration network.
Fig. 5 shows the REG binding collection of the CCE and intertexture CORESET of non-interwoven CORESET.
The duration that assume that the CORESET of intertexture is 1 symbol, and the duration of the CORESET of non-interwoven is 3
A symbol, and the CORESET of the intertexture of 1 symbol is entirely included in the CORESET of the non-interwoven of 3 symbols.
It assume that the binding size in the CORESET of non-interwoven is 1 REG in time-frequency domain and is 3 in the time domain
A REG.It assume that and determine that the quantity for the REG binding for including is concentrated in REG binding according to target AL.
(a) of Fig. 5 shows the CORESET in the CORESET of intertexture for REG the binding collection and non-interwoven of AL 4,8
CCE between relationship.With reference to (a) of Fig. 5, the boundary of REG binding collection and the boundary of CCE are mismatched, therefore exist and cause to provide
The problem of source wastes and blocks.
(b) of Fig. 5 is shown when the AL3 that is introduced into the CORESET to interweave, 6 is collected with configuring REG binding, CCE and is used for
Relationship between the REG binding collection of AL3,6.With reference to
(b) of Fig. 5, the boundary of the REG binding collection for AL 3,6 and the Boundary Match of 1/2 CCE and 1 CCE, because
This, can be minimized the wasting of resources and can reduce blocking probability.Although being not shown, the REG for AL 12 bundlees collection
Boundary and 2 CCE Boundary Match.
Fig. 6 is to show the case where 1 symbol CORESET and 2 symbol CORESET of embodiment according to the present invention overlaps each other
Figure.It assume that 1 symbol CORESET and 2 symbol CORESET overlap each other in 1 region symbol CORESET.
With reference to (a) of Fig. 6, the unit that 2 symbol CORESET can bundle collection with REG interweaves, and respectively from configuration AL3
3 REG binding that 3 CCE of control channel candidate are extracted can configure a REG binding collection.In such a case, it is possible to false
If it is 1 REG in frequency domain and 2 REG in time domain that REG, which bundlees size,.
In this way, being blocked when executing the intertexture based on REG binding collection by the AL1 control channel candidate of 2 symbol CORESET
The CCE of 1 symbol CORESET may be blocked in an identical manner by AL3 control channel candidate.Accordingly, it is possible to will not occur by
Additionally block caused by AL increase.When network configures AL { 1,3,6,12 } in 2 symbol CORESET and executes base to AL6
When the intertexture of REG binding collection, the control channel candidate of AL 1,3,6 blocks (1 symbol CORESET's) identical CCE, thus
Minimize blocking probability.
(b) of Fig. 6 shows the case where not executing intertexture in all CORESET.In this case, 2 symbol
CORESET frequency domain REG binding size be 3 REG, therefore, network need in corresponding CORESET configure AL 1,2,4,
8 }, so that the wasting of resources be advantageously reduced and reduce blocking probability.
Network can not individually signal the configuration (and/or the configuration of REG binding collection) of the AL collection of each CORESET,
And can based on CORESET resource, applied to corresponding CORESET binding size, whether intertexture is executed on CORESET
And/or configuration of overlapping CORESET etc. determines the AL collection (and/or the configuration of REG binding collection) of each CORESET.
For example, when the CORESET for being 1 with frequency domain REG binding size is Chong Die with non-interwoven CORESET, such as Fig. 6 institute
Show, can predefined AL { 1,3,6,12 } to be used, and in this case, can also predefine or configure REG binding
Collect size.This means that determining AL collection and REG binding collection in the following manner, that is, the boundary CCE, REG between overlapping CORESET
Binding boundary and/or REG binding collection boundary etc. can match each other.
Following (i) to (v) set forth the AL collection of embodiment according to the present invention and the determination of REG binding collection size, and
And it can change some parameters.
(i) CORESET of the CORESET and 1 symbol interleaving of 1 symbol non-interwoven
When the REG of the CORESET of 1 symbol interleaving binding size is 2: AL { 1,3,6,12 } and REG binding collection size
=3 REG binding can be configured for the CORESET of 1 symbol interleaving.It is non-that AL { 1,2,4,8 } can be configured for 1 symbol
The CORESET of intertexture.
When the REG of the CORESET of 1 symbol interleaving binding size is 3: AL { 1,2,4,8 } and REG binding collection size
=2 REG binding can be configured for the CORESET of 1 symbol interleaving.It is non-that AL { 1,2,4,8 } can be configured for 1 symbol
The CORESET of intertexture.
(ii) CORESET of the CORESET and 2 symbol interleavings of 1 symbol non-interwoven
When the REG binding size of the CORESET of 2 symbol interleavings is 1 REG in frequency domain and 2 REG in time domain
When: AL { 1,3,6,12 } and REG binding collection size=3 or 6 REG binding can be configured for 2 symbol interleavings
CORESET.AL { 1,2,4,8 } can be configured for the CORESET of 1 symbol non-interwoven.
(iii) CORESET of the CORESET of 1 symbol non-interwoven and 2 symbol non-interwoven
AL { 1,2,4,8 } can be configured for the CORESET of 2 symbol non-interwoven, and AL { 1,2,4,8 } can be matched
Set the CORESET for 1 symbol non-interwoven.
(iv) CORESET of the CORESET and 3 symbol interleavings of 1 symbol non-interwoven
When the REG of the CORESET of 3 symbol interleavings binding is 1 REG in frequency domain and 3 REG in time domain, AL
{ 1,3,6,12 } and REG binding collection size=3 or 6 REG binding can be configured as the CORESET of 3 symbol interleavings.AL
{ 1,2,4,8 } CORESET of 1 symbol non-interwoven can be configured for.
(v) CORESET of the CORESET of 1 symbol non-interwoven and 3 symbol non-interwoven
AL { 1,3,6,12 } can be configured for the CORESET of 3 symbol non-interwoven, and AL { 1,2,4,8 } can be by
It is configured to the CORESET of 1 symbol non-interwoven.
Fig. 7 shows the process of the method for sending and receiving downlink (DL) signal of embodiment according to the present invention.
Fig. 7 shows the example of preceding method, and the present invention is not limited to Fig. 7, therefore, may no longer provide to described above here
Repeated description.
With reference to Fig. 7, base station can send at least one CORESET configuration (705) to UE.For example, base station can be via height
Layer signaling (for example, RRC signaling) transmission includes the first CORESET configuration about the information of the frequency resource of the first CORESET.
Base station can be generated and map PDCCH signal (710).Base station can map PDCCH letter on the first CORESET
Number.Base station can map PDCCH signal by the way that every 2,3 or 6 REG are bundled into 1 REG binding.1 REG can be corresponded to
In 1 symbol in time domain, and it can correspond to 1 resource block (RB) on frequency domain.It base station can be at least for identical
Identical precoding is applied in REG binding.
Base station can send PDCCH signal (715).
UE can receive PDCCH signal (720) by executing blind Detecting to the PDCCH signal on the first CORESET.Example
Such as, UE can receive PDCCH signal by executing the multiple REG of binding on the first CORESET.UE can be at least for belonging to
The REG of identical REG binding uses identical precoding.
UE can obtain DCI (725) from PDCCH signal.
Can be provided in bitmap about include the first CORESET configuration in the first CORESET frequency resource
Information.For example, bitmap can distribute the frequency resource of the first CORESET as unit of 6-RB, so that in every 2,3 or 6 REG quilts
It is bundled into the surplus resources for being not belonging to any REG binding after 1 REG is bundled in the first CORESET.It is wrapped in bitmap
Each of multiple bits included can correspond to 6 RB, and each bit value can indicate corresponding 6 RB whether be
The frequency resource of first CORESET.
Bitmap can be configured specifically for the subband of the UE operation in multiple subbands (for example, BWP).
First CORESET configuration can also include that REG bundlees size information.
It is contemplated that at least partly the REG binding size of twoth CORESET Chong Die with the first CORESET is answered to determine
REG for the first CORESET bundlees size.
Match when for one in the first CORESET and the 2nd CORESET only least partially overlapped with the first CORESET
When setting intertexture, intertexture can be executed based on including the REG binding collection of multiple REG binding.
It can determine that the quantity for the multiple REG binding for including, and multiple REG are concentrated in REG binding according to polymerization grade
Binding can be belonging respectively to different control channel elements (CCE).
About the CORESET that intertexture is not configured, in the first CORESET and the 2nd CORESET, only the first polymerization grade collection
{ 1,2,4,8 } it can be used, and about the CORESET for being configured with intertexture, the second polymerization grade collection { 1,3,6,12 } and first poly-
Conjunction grade collection is also possible to available.
Binding size can be considered applied to the polymerization grade collection of the first CORESET and whether using intertexture, first
At least one of the configuration of CORESET and the configuration of the 2nd CORESET Chong Die with the first CORESET determine.
Fig. 8 is base station (BS) 105 and the UE 110 shown in the wireless communication system 100 of embodiment according to the present invention
The block diagram of structure.The structure of the BS105 and UE 110 of Fig. 8 is only for realizing the embodiment of the BS and UE of the above method, and
The structure of BS and UE according to the present invention are not limited to Fig. 8.BS105 can also be known as eNB or gNB.UE 110 can also be known as using
Family terminal.
Although showing BS105 and UE 110 for simplifying wireless communication system 100, wireless communication system
System 100 may include one or more BS and/or one or more UE.
BS105 may include sending (Tx) data processor 115, Symbol modulator 120, transmitter 125, transmission/reception
Antenna 130, processor 180, memory 185, receiver 190, symbol demodulator 195 and reception (Rx) data processor 197.
UE 110 may include Tx data processor 165, Symbol modulator 170, transmitter 175, send/receive antenna 135, processor
155, memory 160, receiver 140, symbol demodulator 155 and Rx data processor 150.In Figure 12, although an antenna
130 are used for UE 110 for BS105 and antenna 135, but each of BS105 and UE 110 can also be according to need
It to include mutiple antennas.Therefore, BS105 and UE 110 according to the present invention supports multiple-input and multiple-output (MIMO) system.According to
BS105 of the invention can support single user-MIMO (SU-MIMO) scheme and multi-user-MIMO (MU-MIMO) scheme.
In the downlink, Tx data processor 115 receives business datum, received business datum is formatted, to format
The business datum of change is encoded, and is interleaved to the business datum of coding, and data (or the number to intertexture that modulation interweaves
Mapped according to symbol is executed) so that it provides modulation symbol (i.e. data symbol).Symbol modulator 120 receives and processes data symbols
Number and frequency pilot sign so that it provide symbol stream.
120 multiplex data of Symbol modulator and frequency pilot sign, and transmitter is sent by the data of multiplexing and frequency pilot sign
125.In this case, each (Tx) symbol that sends can be the value of data symbol, frequency pilot sign or zero-signal (spacing wave).
In each symbol period, frequency pilot sign can be continuously transmitted during each symbol period.Frequency pilot sign can be FDM symbol
Number, OFDM symbol, time division multiplexing (TDM) symbol or code division multiplexing (CDM) symbol.
Transmitter 125 receives symbol stream, received symbol is converted to one or more analog signals, and in addition adjust one
A or multiple analog signals (for example, the amplification of analog signal, filtering and frequency upooaversion) are suitable for passing through RF so that it is generated
The down link signal that channel carries out data transmission.Then, down link signal is sent to UE by antenna 130.
The configuration of UE 110 described in detail below.The antenna 135 of UE 110 receives DL signal from BS105, and DL is believed
Number it is sent to receiver 140.Receiver 140 executes the adjustment of received DL signal (for example, filtering, amplification and lower turn of frequency
Change), and the signal of adjustment is digitized to be sampled.Symbol demodulator 145 demodulates received frequency pilot sign, and by the knot of demodulation
Fruit is supplied to processor 155 to execute channel estimation.
Symbol demodulator 145 receives the frequency response estimated value for being used for downlink from processor 155, and demodulation institute is received
Data symbol obtains data symbol estim (estimated value of the transmitted data symbol of instruction), and data symbol is estimated
Value is supplied to Rx data processor 150.Rx data processor 150 executes the demodulation of data symbol estim (that is, symbolic solution reflects
Penetrate), demodulation result is deinterleaved, decode deinterleaving as a result, and restore the business datum sent.
The processing of symbol demodulator 145 and Rx data processor 150 and the Symbol modulator 120 and Tx data in BS 205
The processing of processor 115 is complementary.
The Tx data processor 165 of UE 110 handles the business datum in uplink, and provides data symbol.Symbol tune
Device 170 processed receives and OFDM data symbols, and the data symbol of modulation multiplex, it is allowed to provide symbol to transmitter 175
Stream.Transmitter 175 obtains and process symbol stream is to generate uplink (UL) signal, and UL signal is sent by antenna 135
To BS105.The transmitter and receiver of UE/BS can be implemented as single radio frequency (RF) unit.
BS105 receives UL signal from UE 110 by antenna 130.The received UL signal of receiver processing is to be sampled.
Then, 195 process symbol of symbol demodulator, and frequency pilot sign and data symbol estim via extended receiver are provided.
Rx data processor 197 handles data symbol estim, and restores from the received business datum of UE 110.
The processor 155 or 180 of UE 110 or BS105 is ordered or the operation of instruction UE 110 or BS105.For example, UE
The operation of the control of processor 155 or 180, the adjustment and management UE 210 or BS105 of 110 or BS105.Each processor 155 or
180 may be coupled to memory cell 160 or 185, for storing program code and data.Memory 160 or 185 connects everywhere
Device 155 or 180 is managed, so that it can store an operating system, application and general file.
Processor 155 or 180 is referred to as controller, microcontroller, microprocessor, microcomputer etc..Meanwhile it handling
Device 155 or 180 can be realized by various means, for example, hardware, firmware, software or combinations thereof.In hardware configuration, according to
The method of the embodiment of the present invention can realize by processor 155 or 180, for example, one or more specific integrated circuits (ASIC),
Digital signal processor (DSP), digital signal processing appts (DSPD), programmable logic device (PLD), field-programmable gate array
Arrange (FPGA), processor, controller, microcontroller, microprocessor etc..
In firmware or software configuration, the method for embodiment according to the present invention can be to execute above-mentioned functions or operations
The form of module, process, function etc. is realized.The firmware or software realized in the present invention may be embodied in processor 155 or 180
Or in memory cell 160 or 185, it is driven by processor 155 or 180.
Radio interface protocol layers between UE 110, BS105 and wireless communication system (that is, network) can be based on communication
Lower three layers of well known open system interconnection (OSI) reference model are classified as first layer (L1 layers), the second layer (L2 in system
Layer) and third layer (L3 layers).The physical layer for belonging to first layer (L1) provides information transmission service by physical channel.Belong to third
Radio resource between radio resource control (RRC) the layer control UE and network of layer (L3).UE 110 and BS105 can lead to
It crosses cordless communication network and rrc layer exchanges RRC information each other.
Above-described embodiment corresponds to the combination of element and feature of the invention in the form of defined.Also, it removes and non-clearly mentions
And otherwise it can be seen that each element or being characterized in selective.Each element or feature can with cannot with other element or
The form of feature combination is realized.In addition, can be realized of the invention by partly combining element and/or feature
Embodiment.The sequence of operations illustrated for each embodiment of the invention can be modified.Some configurations of one embodiment or
Feature may include that in another embodiment, or can replace the corresponding configuration or feature of another embodiment.Also, it is aobvious
So it is understood that by will match without the claim combinations of clear adduction relationship in the following claims together
Embodiment is set, or can include for new claim by modifying it after submitting application.
Although describe and illustrating the present invention by reference to the preferred embodiment of the present invention, for those skilled in the art
It is readily apparent that without departing from the spirit and scope of the present invention, can carry out various modifications wherein for member
And variation.Therefore, the present invention is directed to cover the modification of the invention come within the scope of the appended claims and their and
Variation.
Industrial feasibility
As described above, present invention could apply to various wireless communication systems.
Claims (14)
1. a kind of method for receiving downlink (DL) signal by user equipment (UE) in a wireless communication system, the method packet
It includes:
The first control resource set (CORESET) configuration is received, the first CORESET configuration includes about the first CORESET
The information of frequency resource;With
Physical downlink control channel is received by bundling multiple resource element groups (REG) on the first CORESET
(PDCCH) signal,
Wherein, the information about the frequency resource of the first CORESET is bitmap;And wherein, the bitmap is with 6-RB
Unit distributes the frequency resource of the first CORESET, so that after every 2,3 or 6 REG are bundled into 1 REG binding,
The surplus resources of any REG binding are not belonging in the first CORESET.
2. according to the method described in claim 1, wherein, the bitmap is used for by specific configuration in multiple subbands UE described in
The subband of operation.
3. according to the method described in claim 1, each of multiple bits for wherein, in the bitmap including correspond to 6-
RB, and each bit value indicate corresponding 6-RB whether be the first CORESET frequency resource.
4. according to the method described in claim 1, wherein, the UE uses identical at least for the REG for belonging to identical REG binding
Precoding.
5. according to the method described in claim 1, wherein, the first CORESET configuration further includes REG binding size information.
6. according to the method described in claim 1, wherein, it is contemplated that second least partially overlapped with the first CORESET
The REG of CORESET bundlees size, determines that the REG applied to the first CORESET bundlees size.
7. according to the method described in claim 1, wherein, when only for the first CORESET and with the first CORESET
When a configuration in the 2nd least partially overlapped CORESET interweaves, based on include the REG binding collection of multiple REG binding come
Execute the intertexture.
8. according to the method described in claim 7, wherein, determine that the REG binding concentrates and include according to polymerization grade described in
The quantity of multiple REG bindings, and the multiple REG binding is belonging respectively to different control channel elements (CCE).
9. according to the method described in claim 7, wherein, in the first CORESET and the 2nd CORESET, relative to not to it
The CORESET to interweave is configured, only the first polymerization grade collection { 1,2,4,8 } is available, and is configured with intertexture relative to it
CORESET, other than the first polymerization grade collection, the second polymerization grade collection { 1,3,6,12 } also be can be used.
10. according to the method described in claim 1, wherein, it is contemplated that for the first CORESET binding size configured and be
In the no configuration to the first CORESET application intertexture and the 2nd CORESET Chong Die with the first CORESET extremely
One few, determination will be applied to the polymerization grade collection of the first CORESET.
11. according to the method described in claim 1, wherein, 1 REG corresponds to 1 symbol in time domain, and corresponds to frequency
1 resource block (RB) on domain.
12. a kind of method for sending downlink (DL) signal by base station (BS) in a wireless communication system, which comprises
The first control resource set (CORESET) configuration is sent, the first CORESET configuration includes about the first CORESET
The information of frequency resource;With
Physical downlink control channel is sent by bundling multiple resource element groups (REG) on the first CORESET
(PDCCH) signal,
Wherein, the information about the frequency resource of the first CORESET is bitmap;And
Wherein, the bitmap distributes the frequency resource of the first CORESET as unit of 6-RB, so that at every 2,3 or 6
REG is bundled into after 1 REG binding, and the remaining money of any REG binding is not belonging in the first CORESET
Source.
13. one kind includes: for receiving the user equipment (UE) of downlink (DL) signal, the UE
Receiver;With
Processor, the processor receive the first control resource set (CORESET) using the receiver and configure, and described first
CORESET configuration includes the information about the frequency resource of the first CORESET, and by tying on the first CORESET
Multiple resource element groups (REG) are tied up to receive physical downlink control channel (PDCCH) signal,
Wherein, the information about the frequency resource of the first CORESET is bitmap;And
Wherein, the bitmap distributes the frequency resource of the first CORESET as unit of 6-RB, so that at every 2,3 or 6
REG is bundled into after 1 REG binding, and the remaining money of any REG binding is not belonging in the first CORESET
Source.
14. one kind includes: for sending the base station (BS) of downlink (DL) signal, the BS
Transmitter;With
Processor, the processor send the first control resource set (CORESET) using the transmitter and configure, and described first
CORESET configuration includes the information about the frequency resource of the first CORESET, and by tying on the first CORESET
Multiple resource element groups (REG) are tied up to send physical downlink control channel (PDCCH) signal,
Wherein, the information about the frequency resource of the first CORESET is bitmap;And
Wherein, the bitmap distributes the frequency resource of the first CORESET as unit of 6-RB, so that at every 2,3 or 6
REG is bundled into after 1 REG binding, and the remaining money of any REG binding is not belonging in the first CORESET
Source.
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CN112312548A (en) * | 2019-07-26 | 2021-02-02 | 北京三星通信技术研究有限公司 | Method and device for receiving physical downlink control channel |
CN112398577A (en) * | 2019-08-16 | 2021-02-23 | 华为技术有限公司 | Method and communication device for processing data |
CN113645705A (en) * | 2021-08-30 | 2021-11-12 | 中信科移动通信技术股份有限公司 | Frequency domain resource allocation method and device |
WO2023193270A1 (en) * | 2022-04-08 | 2023-10-12 | 北京小米移动软件有限公司 | Frequency domain resource configuration method and apparatus |
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KR102363564B1 (en) * | 2017-06-15 | 2022-02-16 | 삼성전자 주식회사 | Method and apparatus for random access and handover |
US11206117B2 (en) * | 2017-09-08 | 2021-12-21 | Lg Electronics Inc. | Method for transmitting or receiving signal in wireless communication system and device therefor |
US11153873B2 (en) * | 2018-09-28 | 2021-10-19 | Qualcomm Incorporated | Resolving time-domain resource allocation ambiguity |
US11239939B2 (en) * | 2019-03-22 | 2022-02-01 | Samsung Electronics Co., Ltd. | Scheduling in communication systems with multiple service types |
KR20200114986A (en) * | 2019-03-29 | 2020-10-07 | 삼성전자주식회사 | Method and apparatus for transmission and reception of control information in wireless communication system |
CN115023923B (en) * | 2020-02-10 | 2023-10-24 | 高通股份有限公司 | Control resource set precoding indication |
US20210314950A1 (en) * | 2020-04-03 | 2021-10-07 | Samsung Electronics Co., Ltd. | Coreset frequency resource configuration for wide-band operation in nr-u |
US20230164801A1 (en) * | 2020-05-14 | 2023-05-25 | Lg Electronics Inc. | Method and apparatus for transmitting/receiving wireless signal in wireless communication system |
CN115190434B (en) * | 2021-04-07 | 2024-04-12 | 上海朗帛通信技术有限公司 | Method and apparatus in a node for wireless communication |
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CN112312548A (en) * | 2019-07-26 | 2021-02-02 | 北京三星通信技术研究有限公司 | Method and device for receiving physical downlink control channel |
CN112398577A (en) * | 2019-08-16 | 2021-02-23 | 华为技术有限公司 | Method and communication device for processing data |
CN113645705A (en) * | 2021-08-30 | 2021-11-12 | 中信科移动通信技术股份有限公司 | Frequency domain resource allocation method and device |
CN113645705B (en) * | 2021-08-30 | 2023-11-21 | 中信科移动通信技术股份有限公司 | Frequency domain resource allocation method and device |
WO2023193270A1 (en) * | 2022-04-08 | 2023-10-12 | 北京小米移动软件有限公司 | Frequency domain resource configuration method and apparatus |
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EP3468276A1 (en) | 2019-04-10 |
US10687322B2 (en) | 2020-06-16 |
KR20180134760A (en) | 2018-12-19 |
JP2019530319A (en) | 2019-10-17 |
EP3468276B1 (en) | 2021-09-15 |
WO2018225998A1 (en) | 2018-12-13 |
KR101988322B1 (en) | 2019-06-12 |
JP6746779B2 (en) | 2020-08-26 |
CN109479293B (en) | 2020-07-17 |
EP3468276A4 (en) | 2020-01-22 |
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